JP2012510019A - Platform for capturing wave energy - Google Patents

Abstract

A platform for capturing wave energy suitable for deep water and ultra deep water is supported on an underwater hull (2) by hydrodynamic struts (3) arranged uniformly along each side. Cover (1). The platform has a V-shaped planar shape and turns itself so that the wavefront travels perpendicular to the plane of symmetry. Wave energy is placed between the struts (3) on each side of the platform and is absorbed by each acquisition module (4) that gradually contacts the waves as the waves move forward, and the periodic motion of the waves is continuous. Can be converted into motion. The platform is stabilized using a large ballast (8) connected to the lower end of the pivot (10) by means of a mooring line (9) and automatically placed at the appropriate position at all times.
[Selection] Figure 1

Description

  The present invention relates to the technical field related to renewable energy, more specifically wave energy.

  The use of the ocean as an energy source that does not cause pollution has long been considered. Because waves are all over the world, have low environmental impact and are predictable, the energy gained from wave swells is the most powerful.

  In Japan, India, Norway, the United States, Denmark, United Kingdom, Ireland and Portugal, devices have been developed to extract energy from waves. There are various options for these devices and some prototypes are already in operation.

  The designs being tested can be categorized as coastal fixed types and floating body types that capture offshore wave energy. The following concept is used to convert wave swell into energy.

  Oscillating water column type system: An oscillating water column type system is a structure located partially in water with an opening through which a wave enters the base. The internal water column moves up and down. As the water level rises, air passes through the turbine and is reactivated when it is sucked back from the turbine. Oscillating water column type systems are usually installed on the coast (some are floating).

  Closed system: A closed system collects impinging water and operates one or more turbines. A wave is made to flow into the reservoir and the stored water is supplied to the turbine. Big waves are necessary for overtopping. There are floating type and coastal type.

  Absorber-type system: The absorber-type system uses wave oscillation and converts it into energy by mechanical or hydraulic means.

  Some absorber-type systems are composed of articulated float members for converting wave motion into electrical energy. A hydraulic pump is accommodated in the connecting portion. The forward and backward movement causes the connecting portion to bend and the hydraulic pump to start operation, sending high pressure fluid to the hydroelectric generator.

  Others use energy obtained from vertical vibration of waves through a buoy that moves up and down on a structure in which a hydraulic pump is installed. Water enters and exits the pump and drives the generator.

  Pendulum type system: The pendulum type system is suitable for installation on a breakwater. The pendulum type system consists of a water chamber with a steel plate placed towards the sea, connected at the top and rigid enough to vibrate slightly by the action of waves. The steel plate is moved by the ripples in the water play chamber, and the vibration is transmitted and absorbed by a hydraulic or pneumatic mechanism.

  The offshore wave energy density is more than twice the coastal wave energy density, but most designs for utilizing wave energy are used at or near the coast and output is low.

  An object of the present invention is to provide a suitable solution to the above-described problem.

  The present invention is a semi-submersible platform suitable for operation in deep and ultra deep waters and includes at least one cover supported on a hull (hereinafter referred to as “platform”) for capturing wave energy. About). The hull can be brought to an appropriate height by filling it with water and can be submerged in the water so that the platform is well stabilized even in the case of strong wave swells.

  The platform has a V-shaped planar shape and turns itself so that the wavefront travels perpendicular to the plane of symmetry. Thus, the wave gradually and simultaneously hits a small area (compared to the platform) on each side of the platform and moves until it overflows. This simplifies the stabilization system.

  The wave energy is absorbed by each acquisition module that is uniformly distributed along each side of the platform. With this configuration, the acquisition module on each side can gradually contact the wave as the wave moves forward, converting the periodic motion of the wave into a continuous motion.

  The captured energy is converted into usable energy (usually electricity). Other methods of use include desalting and hydrogen production.

  Transmission of energy from each capture module to a generator or the like can be performed mechanically, using a fluid as a transmission element, or a combination thereof.

  Generators can be connected to a single base to pool generation capacity. Also, other energy receiving devices can be interconnected depending on the purpose.

  The platform is stabilized by a fastening system including a large ballast connected to the lower end of the pivot axis by a mooring line and is always automatically placed in the proper position.

  In order to facilitate understanding of the present invention, the drawings show an embodiment of the present invention as an example.

1 is a perspective view of a design that includes the basic elements of a platform. FIG. Examples of the capture module, the location of the capture module on the platform, the components comprising the capture module, and a mechanism for transferring energy to a coupled transmission shaft common to all capture modules located on one side of the platform . FIG. 2 is a plan view of components of a capture / transmission / power generation system on the right side of the platform.

  The platform of the present invention comprises a cover (3) supported on an underwater hull (2) by a strut (3) having a hydrodynamic profile that is arranged uniformly along each side and changes direction according to the direction of wave travel. 1).

  The passage formed by the two adjacent struts (3) communicates with the outside so that water flows inside the platform.

  The platform changes its direction so that the wavefront moves towards the platform perpendicular to the plane of symmetry. According to this configuration, when the wave reaches the platform, it is divided (broken) by the colliding strut (3), and a part of the wave passes through the passage.

  Wave energy is absorbed by each capture module (4) located between the struts (3) on each side of the platform. The energy absorbed by the same side capture module (4) is transmitted to the corresponding articulated transmission shaft (15). The connecting transmission shaft (15) on each side includes a receiving gear (14), a transmission rod (16), and a cardan joint (17) that connects the shaft of the receiving gear (14) to the transmission rod (16). Including.

  The capture module (4) comprises a floater (5) whose lower part is connected to the shaft (6) and moves in the undulation (bump) direction.

  The capture module (4) is arranged in the wave entrance area in the passage in a water chamber defined by two struts (3) in the lateral direction and in the lower part by a ramp (7) fixed to the strut (3). Has been. According to this configuration, a part of the wave that has entered each passage interacts with the corresponding acquisition module (4) to obtain kinetic and potential energy.

  The higher the lamp (7) height (which may be variable), the more energy can be captured at a given wave magnitude. The height of the ramp (7) is determined such that the water chamber where the capture module (4) is located is drained when a part of the following wave begins to enter the water chamber. Therefore, the ramp (7) must be such that a wave of a predetermined magnitude partially passes over the ramp (7) and is drained from the basin to the internal area of the platform. Therefore, it is necessary to determine the height range of the lamp (7) according to the wave size.

  The energy absorbed by each capture module (4) is transmitted to the free pinion (12) by the gear ring (11), and the coupled transmission shaft corresponding to the line of the capture module (4) by the transmission engagement of the pinion (13). It is transmitted to the receiving gear (14) of (15).

  The plurality of capture modules (4) on the same side always supply energy to the coupled transmission shaft (15), and the energy is transmitted to one or more generators (19). Since the rotational speed of the coupled transmission shaft (15) is low, the generator receives energy via the speed increaser (18).

  The pinion (12) does not operate when the floater (5) moves upward when energy is captured, but only when it moves downward. When the water is discharged, the pinion (12) operates and the floater (5) moves downward with a predetermined delay time to prevent free fall. Accordingly, the floater (5) moves in a floating state, and at the same time, the absorbed energy is transmitted to the coupled transmission shaft (15). By this process, the upward and downward movement of the floater (5) is converted into rotation.

  The performance of the connection mechanism on each side surface is maximized when the wave period matches the period of the floater (5). However, considering that the wave cycle changes, the cycle of the floater (5) is matched to the wave cycle. The underwater volume of the floater (5) can be adjusted to the given operating conditions. If the underwater volume of the floater (5) is fixed, the period can be adjusted by changing the torque. This can be done by actuating or stopping the generator (19) on the side.

  Due to the angle with respect to the wavefront, the two rows of capture modules (4) are actuated gradually during forward movement and can continuously rotate the connected transmission shaft (15). Thereby, a low frequency can be converted into a high frequency necessary for generating electric energy.

  Undesirable stresses are removed by the articulated transmission shaft (15) and can accommodate changes in angle without affecting the efficiency of the mechanism.

  In order to ensure continuous motion, the length of the platform in the wave propagation direction must be greater than the maximum wavelength of the wave at that location. As a result, the wave reaches the platform before the preceding wave flows across the platform.

  The platform is stabilized by a fastening system that includes two large ballasts (8) connected to the lower end of the pivot axis (10) by a mooring line (9).

  The fastening system is simplified by two ballasts (8). Also, in this case, it is not necessary to keep the platform on the sea surface with a small tolerance radius like an oil platform. However, the position of the platform is not a decisive factor and the tolerance radius may be larger. As a result, platform movement is limited to an area sized according to the stiffness of the ballast system. In any case, movement within the set tolerance radius does not adversely affect the operation of the platform. At rest, the mooring line (9) and the pivot axis (10) are theoretically located on a vertical plane.

  When the platform turns in the swell direction, a similar thrust is applied to both sides, and the platform remains in that position. When the swell direction changes, a difference occurs in the horizontal thrust of the wave with respect to the side surface of the platform, and a moment is generated that rotates the platform about the pivot axis (10) and pushes it to a new balance position in the correct orientation. The rotation of the pivot axis (10) is prevented by the ballast system. Since the power line (20) is fixedly connected to the turning shaft (10), it cannot rotate.

  There may be a complementary dynamic positioning system with radar, sonar and computer actuated screws for proper placement of the platform in an emergency.

  Note that the length of the platform must be greater than the wavelength of the long wave at that location. A shape whose length is about half the width may be preferred. Therefore, in a place where a wave having a wavelength of 150 m is generated, the length of the platform can be 160 m and the width can be 320 m.

  The wave energy generated by the platform varies depending on the position and size of the platform. Wave energy varies depending on the area, and the greater the platform width, the greater the energy generated. The width matches the length of the wavefront. The theoretical wave energy generated by the platform is obtained by multiplying the width (m) of the platform by the average energy of a 1 m wavefront. Under the same conditions as in the previous paragraph (platform width is 320 m), the wave has an average energy of 60 kW / m (common on the Atlantic coast of Europe), the theoretical wave energy that can be generated is 19 .2 MW.

  A control device, a transportation system, and a conversion device can be shared by a group of devices arranged in a predetermined range.

  As is apparent from the above description and drawings, the platform of the present invention has advantages over existing devices used for similar purposes.

  First, the platform of the present invention allows wave energy capture modules to be installed in deep and ultra-large waters far from the coast with better wave conditions and very high production capacity / occupied surface ratio. it can. In addition, the installation offshore has a great environmental advantage.

  In locations far from the coast where there is ample space, unlike many energy plants, the platform location does not require conditioning and can be installed in a suitable location for operation.

  Also, the platform is a movable resource because it is not permanently fixed to the seabed. If necessary, the platform can be removed and pulled to another location.

  Also, the ability to share a floating structure by two capture systems is very beneficial due to its large size. Installing a wind generator on the platform can solve one of the problems in the wind energy sector. That is, many advantages can be obtained by installing the wind power generator offshore as compared with the case of installing the wind power generator on land, on the coast, or in the vicinity thereof.

Claims (3)

A platform for capturing wave energy,
Having a V-shaped (triangular airfoil) planar shape and changing its direction so that the wavefront moves toward the platform perpendicular to the plane of symmetry;
It has a hydrodynamic profile that changes its direction according to the forward movement direction of the wave, and is arranged uniformly along the side surface of the platform to form a passage communicating with the outside, and a wave moving forward passes through the passage. At least one cover (1) supported on the underwater hull (2) by a strut (3) that gradually divides
Each capture module (4) is connected to the shaft (6) at the bottom and includes a floater (5) that moves in a swell direction, defined laterally by the two struts (3) and at the bottom the struts (3 In the water chamber defined by the ramps (7) fixed to), arranged in the wave entrance region in said passages, interacting part of the waves entering each passage with the corresponding capture module (4), A plurality of acquisition modules (4) that absorbs kinetic and potential energy and transmits the kinetic and potential energy via a gear ring (11) to a free pinion (12) that transmits the kinetic and potential energy by rotation in a single direction. )When,
A fixing system comprising a ballast (8) connected to the lower end of the pivot (10) by means of a mooring line (9), which automatically places the platform in the proper position at all times;
A platform characterized by including:   Each free pinion (12) is common to all the capture modules (4) on the same side due to the transmission engagement of the pinion (13), and includes a receiving gear (14), a transmission rod (16), Energy is transmitted to each receiving gear (14) of the coupled transmission shaft (15) including a cardan joint (17) connecting the shaft of the receiving gear (14) to the transmission rod (16). The platform according to claim 1.   The connected transmission shaft (15) is adapted to transfer the energy supplied by the capture module (4) on the side of the connected transmission shaft (15) via a gearbox (18) to one or more generators (19 The platform according to claim 2, wherein:

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